CN205839015U - A kind of multi-joint bioreactor system - Google Patents

Abstract

The utility model discloses a multi-connected bioreactor system, which comprises an integrated cabinet, a processing device, and N sets of biological reaction monitoring devices arranged on the integrated cabinet, where N≥2 and N is a natural number; the biological reaction The monitoring equipment includes a bioreactor for cultivating microorganisms and a monitoring device for monitoring the bioreactor; the monitoring devices are respectively electrically connected to the processing equipment and send the monitored experimental data to the processing equipment; the processing equipment includes a display, and simultaneously displays the experimental data monitored by the monitoring devices on the display. Compared with the existing technology, the data in multiple microbial reactors can be compared and analyzed through one processing device, which can improve work efficiency, and the monitoring data can be sent to the monitor that can display the experimental data at the same time, which is convenient for the experimenter to quickly and intuitively Compare experimental data.

Description

A kind of multiple bioreactor system

technical field

The utility model relates to a bioreactor system, in particular to a multi-connected bioreactor system.

Background technique

A bioreactor is a device that uses living cells or enzymes as biocatalysts to provide a suitable environment for cell proliferation or biochemical reactions. In the process of biochemical reaction, it is necessary to monitor the situation in the bioreactor in real time and collect a large amount of experimental data, so as to analyze and compare the data and obtain the optimal culture conditions.

The bioreactors in the prior art are all independently designed, and each bioreactor can only monitor one cultivation process. However, a complete cultivation period for some organisms can take as long as one month. If only one bioreactor is used for repeated comparative experiments, the cultivation period will be extremely long. If the experimenter uses multiple bioreactors to conduct comparative experiments at the same time, each bioreactor needs to be equipped with separate processing equipment, which is not only expensive, but also reflects the culture data and curves independently of different bioreactors, which cannot Parallel comparison on the same interface will seriously affect the accuracy of data comparison.

Therefore, how to monitor the bioreactor in real time in the shortest time, quickly obtain accurate experimental data and display it on the same interface, so that it is convenient for the experimenter to observe the data results and obtain the optimal culture conditions is the problem to be solved by the present invention .

Utility model content

The purpose of this utility model is to provide a multi-connected bioreactor system, so that the experimenters can compare and analyze the data in multiple microbial reactors through one processing device, so that the cultivation period of microorganisms can be shortened, and the monitoring data can be sent to The monitor that can display the experimental data at the same time is convenient for the experimenter to quickly obtain accurate experimental data.

In order to solve the above technical problems, the embodiment of the utility model provides a multi-connected bioreactor system, including: an integrated cabinet, a processing equipment, N sets of biological reaction monitoring equipment arranged on the integrated cabinet, N≥ 2 and N is a natural number; the biological reaction monitoring equipment includes a bioreactor for cultivating microorganisms and a monitoring device for monitoring the bioreactor; each of the monitoring devices is electrically connected to the processing equipment and the The monitored experimental data is sent to the processing device; the processing device includes a display, and the experimental data monitored by the monitoring devices are simultaneously displayed on the display.

Compared with the prior art, the embodiment of the utility model is that the multiple bioreactor system consists of an integrated cabinet, a processing device and N sets of biological reaction monitoring devices arranged on the integrated cabinet. Through a processing device to compare and analyze the data in multiple microbial reactors to improve work efficiency, the monitoring device sends the monitored experimental data to the processing device; since the processing device contains a monitor, and the monitors are displayed on the monitor at the same time The experimental data monitored by the device is convenient for the experimenters to quickly and intuitively compare the experimental data.

In addition, the multiple bioreactor system further includes a storage device for storing the experimental data, and the storage device is electrically connected to the processing device. A large amount of experimental data can be stored through the storage device, so that the processing device can quickly and accurately obtain experimental data and record and query historical data.

In addition, the multiple bioreactor system also includes a communication device, a cloud server, and a mobile terminal. The processing device is electrically connected to the communication device and uploads the monitored experimental data to the In the cloud server, the mobile terminal reads or downloads the experimental data in the cloud server through wireless signals. The monitored experimental data is uploaded to the cloud server through the communication equipment, and the mobile terminal reads or downloads the experimental data in the cloud server through the wireless signal, so that the remote monitoring of the mobile terminal can be realized.

In addition, the mobile terminal is a mobile phone and/or a tablet computer. When the experimenter is not in the laboratory, it is convenient for the laboratory personnel to understand the relevant data in the experiment anytime and anywhere, and at the same time, it is convenient for the experimenter to carry.

In addition, the integrated cabinet is provided with positioning grooves matching the bioreactors, and the bioreactors are respectively located in the positioning grooves. In order to fix the bioreactor on the integrated cabinet more stably, the integrated cabinet is equipped with a positioning groove for the bioreactor.

In addition, the monitoring device includes a weighing device for weighing the bioreactor; the weighing devices are respectively arranged at the bottom of each positioning groove and are respectively electrically connected to the processing equipment. The bioreactor is weighed by the weighing device, and the detection device obtains the weighing data of the bioreactor, thereby realizing the monitoring of the weight of the bioreactor.

In addition, the surface of the integrated cabinet is provided with collection line quick-connect joints respectively connected to the material source, water source, power supply, and gas source. Wire quick connector connection. Since the surface of the integrated cabinet is equipped with quick-connect joints for connecting the material source, water source, power supply, and gas source respectively, the material pipelines, water pipelines, electric pipelines, and gas pipelines of each bioreactor are respectively connected to the quick-connect joints of the collection lines. There is no need for secondary piping, which is convenient for experimenters to operate, and at the same time avoids exposed pipelines on site, making the culture environment clean and tidy.

In addition, pipelines, pumps, instruments, and electrical control components matching the bioreactor are fixed in the integrated cabinet. By fixing the pipes, pumps, instruments, and electrical control components that match the bioreactor, the required living and nutritional conditions can be improved for the microorganisms, and a clean culture environment can be provided. At the same time, due to the high integration of integrated cabinet equipment, the equipment occupies less laboratory space.

In addition, rollers are provided under the integrated cabinet. When it is necessary to transfer the integrated cabinet, since there are rollers under the integrated cabinet, it is convenient for experimenters to carry it.

Description of drawings

Fig. 1 is the schematic structural diagram of the multiple bioreactor system in the first embodiment of the present invention;

Fig. 2 is a schematic diagram of the connection mode of the multiple bioreactor system in the second embodiment of the present invention.

detailed description

In order to make the purpose, technical solutions and advantages of the present utility model clearer, various implementation modes of the present utility model will be described in detail below in conjunction with the accompanying drawings. However, those of ordinary skill in the art can understand that in each implementation manner of the present utility model, many technical details are proposed in order to enable readers to better understand the present application. However, even without these technical details and various changes and modifications based on the following implementation modes, the technical solution claimed in each claim of the present application can be realized.

The first embodiment of the utility model relates to a multiple bioreactor system. As shown in FIG. 1 , the multiple bioreactor system is composed of an integrated cabinet 2 , a processing device 3 and bioreaction monitoring equipment arranged on the integrated cabinet 2 .

Wherein, the bioreaction monitoring equipment is composed of a bioreactor 1 for cultivating microorganisms and a monitoring device 5 for monitoring the bioreactor 1; each monitoring device 5 is connected to the processing device 3 through a data line respectively, and the monitored The experimental data is sent to the processing device 3; the processing device 3 simultaneously displays different experimental data through the display.

It is not difficult to find out from the above that the monitoring device 5 transmits the experimental data obtained by monitoring the bioreactor 1 to the processing device 3 through the data line, and the experimental data in the processing device 3 is displayed in the form of a chart through the display . The multi-bioreactor system can compare and analyze the experimental data of multiple bioreactors 1 through one processing device 3 to improve the work efficiency of the experimenters and send the monitoring experiment data to On the monitor that can display the experimental data at the same time, it is convenient for the experimenters to quickly and intuitively compare the experimental data, and then select the optimal culture conditions.

Specifically, in this embodiment, as shown in Figure 1, the upper surface of the integrated cabinet 2 is provided with multiple bioreactors 1, and the bioreactors 1 are provided with material source pipelines, water source pipelines, power lines, and gas sources. Pipeline interface, wherein, on the position where the upper surface of the integrated cabinet 2 cooperates with the bioreactor 1, there is a quick-connect joint 4 connecting the material source, water source, power supply, and gas source, and the processing equipment 3 is connected to the integrated cabinet 2 through a data line. The monitoring device 5 is connected.

Furthermore, in this embodiment, since each bioreactor 1 needs to be connected to external water, electricity, and gas separately, it is very troublesome, and a large number of related connecting pipelines can only be exposed outside, making the cultivation environment chaotic. To avoid the above-mentioned problems, the pipelines, pumps, instruments, and electrical control components that match the bioreactor 1 can be fixedly installed in the integrated cabinet 2, so that the equipment in the integrated cabinet 2 is highly integrated, reducing the equipment’s occupation of laboratory space, and providing more resources for biological cultivation. A clean culture environment can eliminate the need for secondary piping, avoid the phenomenon of exposed pipelines on site, facilitate the operation of experimenters, and make the culture environment clean and tidy. It is worth mentioning that during the experiment, it is necessary to provide nutrients and necessary environmental conditions for the organisms in the bioreactor 1 to ensure the normal activities of the organisms. The quick-connect connector 4 of the power supply and gas source, when it is necessary to provide nutrients and necessary environmental conditions for the organism, only needs to connect the material pipeline, water pipeline, electric pipeline, and gas pipeline of the bioreactor 1 to the quick connection of the hub. When the connector 4 is connected, the nutrients will enter the bioreactor 1 through the pipelines on the bioreactor 1, so that the organisms can move normally. In addition, the entry of nutrients and gases into the bioreactor 1 is controlled by a power switch.

It should be noted that, in order to fix the bioreactor 1 on the integrated cabinet 2 more stably, the integrated cabinet 2 is provided with a positioning groove matching the bioreactor 1, wherein the positioning groove is a circular inner groove with a depth of three centimeters , the upper part of the groove is provided with a support frame that can adjust the height of the bioreactor 1, and the support frame and the groove are independent components. In the actual application process, in order to better fix the bioreactor 1, the support frame and the groove can also be integrally formed. In this embodiment, the process method will not be described in detail.

In addition, in the actual use process, the integrated cabinet 2 needs to be transported. In order to reduce the workload of the experimenters, rollers 6 are added below the integrated cabinet 2, and the rollers 6 are located on the corners of the lower surface of the integrated cabinet 2. When the experimenters When transferring the integrated cabinet 2, since the integrated cabinet 2 has rollers 6 under it, the rollers 6 can drive the integrated cabinet 2 to move, thereby facilitating the experimenters to carry the integrated cabinet 2.

In an actual process, the monitoring device 5 includes a weighing device for weighing the bioreactor 1; each weighing device is directly connected to the processing equipment 3 through a data line. The bioreactor 1 is weighed by a weighing device to obtain weighing experiment data, and then monitor the bioreactor 1 . It should be noted that when more bioreactors 1 are needed for the cultivation experiment, the number of bioreactors 1 can be increased at will in order to obtain more comparative experimental data, wherein, in this embodiment, as preferred, the bioreactor There are four devices 1, and they are placed side by side in the positioning groove of the integrated cabinet 2. Among them, the weighing device converts the weight of the bioreactor 1 into an electrical signal through the pressure sensor, and transmits the electrical signal to the processing device 3. When the processing device 3 receives the electrical signal, it converts the electrical signal into a graph and displays it on the display. come out.

In addition, in this embodiment, the experimenters need a large amount of data for comparison. At the same time, in order to facilitate the experimenters to view the experimental data, the multi-bioreactor system is also equipped with a storage device for storing the experimental data. The storage device communicates with the The processing device 3 is connected, and since the storage device can store a large amount of experimental data, the experimenter can quickly and accurately obtain the experimental data and query the historical records through the processing device 3 .

The second embodiment of the utility model relates to a multiple bioreactor system. As shown in Figure 2, the second embodiment of the present utility model is a further improvement on the first embodiment. mobile terminal 10.

In the actual application process, because the experimenters are responsible for multiple laboratories, they need to observe each laboratory. Due to the limited number of experimenters, it is impossible to observe the data of each bioreactor 1 in real time. In order to facilitate the experimenters at any time Understand the relevant data of the experiment and observe the monitoring results at any place. In this embodiment, remote monitoring using the mobile terminal 10 can be realized.

Further, the monitoring device 5 will monitor the experimental data obtained by the bioreactor 1, and the monitoring device 5 will transmit the experimental data to the processing device 3 through the data line. Since the processing device 3 and the communication device 8 are connected through the data line, the processing device 3 The received experimental data is transmitted to the communication device 8 through the data line, and finally the communication device 8 uploads the monitored experimental data to the cloud server 9 in real time, and the experimenter can read or download the latest update in the cloud server 9 through the wireless signal of the mobile phone. The latest experimental data read or downloaded will be displayed on the screen of the mobile phone. When the experimenter needs to monitor the laboratory monitoring data at a certain moment, he only needs to turn on the mobile phone, and the experimental data can be clearly displayed on the mobile phone screen. On the one hand, the bioreactor 1 is monitored in the shortest time, and the accurate experimental data can be quickly obtained and displayed on the same interface, which is convenient for the experimenter to observe the data results and their changes, and obtain the optimal culture conditions. It should be noted that, in this embodiment, in order to achieve portability, the mobile terminal 10 may be a mobile phone or a tablet computer with a screen.

Those of ordinary skill in the art can understand that the above-mentioned embodiments are specific examples for realizing the utility model, and in practical applications, various changes can be made to it in form and details without departing from the utility model spirit and scope.

Claims (9)

1. a multi-joint bioreactor system, it is characterised in that comprise: integrated cabinet, It is nature that processing equipment, N are set on the biological respinse monitoring device on described integrated cabinet, N >=2 and N Number；

Described biological respinse monitoring device comprises the bioreactor for cultivating microorganism, for monitoring The monitoring device of described bioreactor；

Described each monitoring device is electrically connected with described processing equipment the experimental data that will be monitored Send to described processing equipment；

Described processing equipment comprises display, and shows described each monitoring the most simultaneously The experimental data that device is monitored.

Multi-joint bioreactor system the most according to claim 1, it is characterised in that described many Connection bioreactor system also comprises the storage device for storing described experimental data, described storage device It is electrically connected with described processing equipment.

Multi-joint bioreactor system the most according to claim 1, it is characterised in that described many Connection bioreactor system also comprises communication apparatus, cloud server, mobile terminal, described processing equipment It is electrically connected with described communication apparatus and by described communication apparatus, the experimental data monitored is uploaded to In described cloud server, described mobile terminal is read by wireless signal or downloads described cloud server In experimental data.

Multi-joint bioreactor system the most according to claim 3, it is characterised in that described shifting Dynamic terminal is mobile phone and/or panel computer.

Multi-joint bioreactor system the most according to claim 1, it is characterised in that described collection Becoming cashier's office in a shop to be provided with the locating slot coordinating described bioreactor, described each bioreactor lays respectively at described In each locating slot.

Multi-joint bioreactor system the most according to claim 5, it is characterised in that described prison Survey device and comprise the weighing device for weighing described bioreactor weight；

Described each weighing device be separately positioned on bottom described each locating slot and respectively with described processing equipment It is electrically connected with.

Multi-joint bioreactor system the most according to claim 1, it is characterised in that described collection Cabinet surface configuration is become to have junctional complex material source, water source, power supply, the line concentration quick union of source of the gas respectively, described The material pipeline of each bioreactor, water pipeline, electric line, gas pipeline connect soon with described line concentration respectively Head connects.

Multi-joint bioreactor system the most according to claim 1, it is characterised in that described collection It is fixed with in becoming cabinet and coordinates the pipeline of described bioreactor, pump, instrument, electric controling element.

Multi-joint bioreactor system the most according to claim 1, it is characterised in that described collection The lower section becoming cabinet is provided with roller.